DE202019101232U1 - Spring contact pin - Google Patents

Abstract

Spring contact pin with an electrically conductive tubular housing (2), in which an electrically conductive piston acted upon by a compression spring (6) is guided, the free piston end (10) protruding from the housing (2) in electrical contact with an electronic component of a test object (17) can be brought, the housing (2) having a circumferential end stop (5) on the inside for the piston and the piston having a first piston part (7) resting on the compression spring (6) and a second piston part (8), wherein each piston part (7, 8) has a cross-sectionally round base region (7a, 8a) and a cross-sectionally semicircular axial region (7b, 8b), the two axial regions (7b, 8b) being arranged next to one another transversely to the axial direction (A) and at the free end each have a wedge surface (7c, 8c) which bears on a corresponding wedge surface (8d, 7d) of the base region (8a, 7a) of the other piston part 88,7), such that s the two piston parts (7, 8) are pressed against the inner wall of the housing (2) by the pressure spring, characterized in that the piston has a third piston part (9) which bears against the end stop (5) of the housing (2), protrudes from the housing (2) with its free contact end (10) and is pivotally connected with its other end (12) to the second piston part (8) with respect to the axial axis (A).

Description

The invention relates to a spring contact pin with an electrically conductive tubular housing, in which an electrically conductive piston acted upon by a compression spring is guided, the free piston end of which protrudes from the housing can be brought into electrical contact with an electronic component of a test object, the housing on the inside has a circumferential end stop for the piston and wherein the piston has a first piston part bearing against the compression spring and a second piston part, each piston part each having a cross-sectionally round base region and a cross-sectionally semicircular axial region, the two axial regions being arranged next to one another as seen transversely to the axial direction and each have a wedge surface at the free end, which lies against a corresponding wedge surface of the base region of the other piston part, such that the two piston parts are acted upon by the compression spring against the inner wall nd of the housing.

Such spring contact pins are basically known. They are used to make contact with an electrical device under test (e.g. electronic components, circuit boards or cable harnesses). An electrical connection to the test object is established by the contacting so that it can be subjected to an electrical functional test or the like. Depending on the design of the electrical test specimen to be tested, a more or less good contact contact is possible, with relatively large electrical currents often also being to be transmitted in the contact contact. For this purpose, spring contact pins with the features of the preamble of claim 1 have long been known. Such a spring contact pin has a two-part piston with a wedge gear, which ensures that the piston is pressed radially outwards over the entire surface against the inner wall of the housing by deflecting the axially directed spring force, and thus a large and defined current transfer area is available from the housing to the piston . With these spring contact pins, the contact between the free piston end and the electronic component of the test object can only be made in the axial direction.

However, there are also test specimens in which the electronic component to be contacted is not accessible in the axial direction. The known spring contact pins are not suitable for such test specimens.

The object of the invention is to provide a spring contact pin suitable for high-current transmission, which is also suitable for test processes on test specimens which deviate from the axial contacting direction.

This object is achieved according to the invention in a spring contact pin of the type mentioned at the outset in that the piston has a third piston part which abuts the end stop of the housing, projects with its free contact end out of the housing and can be pivoted with its other end with the second piston part relative to the axial axis connected is.

The spring contact pin thus has a three-part piston, the first two piston parts ensuring a large current transfer area from the housing to the piston, as in known spring contact pins, and the third piston part, which makes contact with the test object with its free contact end, is pivotable with respect to the axial axis with the second piston part is connected, so that a contact deviating from the axial contact direction is also possible. For example, the device under test can have a socket-shaped receptacle with a laterally arranged electrical contact and a leaf spring or the like can be arranged within the socket, which deflects the free contact end of the third piston part accordingly when the contact element is inserted into the socket-shaped receptacle.

It is preferably provided that the third piston part has a spherical region which bears against the end stop of the housing. This spherical area interacts on the one hand with the end stop and on the other hand enables the pivoting movement with respect to the axial axis.

In order to ensure a good electrical connection between the third and the second piston part, it is preferably provided that the second piston part has a front indentation and the third piston part has a corresponding front end bulge.

According to a first embodiment, it is provided that the front indentation is wedge-shaped and the front indentation is wedge-shaped. If the free contact end of the third piston part is deflected relative to the axial axis, this leads to the wedge-shaped, front-side bulge moving the wedge-groove-shaped, front-side recess on the second piston part radially outwards and slightly in the axial direction against the spring force, so that at the same time an even greater pressure of the first and the second piston part on the inner wall of the housing.

Alternatively, it can also be provided that the front indentation is concave and the front indentation is convex. The The indentation and the bulge are then preferably conical, spherical or spherical. In this embodiment, the third piston part can be deflected by 360 ° in two axis directions.

• 1 eine Draufsicht auf einen Federkontakt,
• 2 einen Längsschnitt durch den gegenüber 1 um 90° gedrehten Federkontakt nach 1 mit Prüflingseingriff ohne Auslenkung des dritten Kolbenteiles,
• 3 einen Längsschnitt gemäß 2 mit Auslenkung des dritten Kolbenteiles,
• 4 ein vergrößertes Detail X der 2 und
• 5 ein vergrößertes Detail Y der 3.

The invention is explained in more detail below using the drawing as an example. These show in

• 1 a top view of a spring contact,
• 2nd a longitudinal section through the opposite 1 spring contact rotated by 90 ° 1 with test specimen intervention without deflection of the third piston part,
• 3rd a longitudinal section according to 2nd with deflection of the third piston part,
• 4th an enlarged detail X of the 2nd and
• 5 an enlarged detail Y of 3rd .

A spring contact pin is generally designated 1 in the figures. This spring contact pin 1 has a tubular housing 2nd on, which consists of an electrically conductive material, such as brass. Here is the case 2nd at its rear end with a tapered area with an external thread 3rd provided on which a sleeve 4th is screwed on, which is used for electrical connection with a connection cable, not shown. The sleeve 4th can also be made in one piece with the housing 2nd be executed.

At the front end area is the sleeve 2nd provided with an all-round flare that has an end stop on the inside 5 forms. Inside the case 2nd is a compression spring adjacent to the rear end 6 arranged, which on a multi-part piston of the spring contact pin 1 is present. This piston consists of three parts, namely a first piston part 7 , a second piston part 8th and a third piston part 9 . All three piston parts 7 , 8th , 9 also consist of an electrically conductive material. The third piston part 9 protrudes in some areas with its free piston end 10th out of the case 2nd out, but due to the end stop 5 in the housing 2nd no further than shown from the housing 2nd slide out as there is a spherical area 11 has, due to the load from the compression spring 6 all around at the end stop 5 is present.

The first piston part 7 on which the compression spring 6 has a cross-sectionally round base area 7a on in a cross-sectionally semicircular axial area 7b transforms. The second piston part 8th also has a cross-sectionally round base area 8a and adjacent to it a cross-sectionally semicircular axial area 8b on. Here are the two axial areas 7b and 8b Seen next to each other transversely to the axial direction, so that they complement each other to form a round piston area.

At the free end, each axial area has 7b , 8b one wedge surface each 7c , 8c on that correspond to a wedge surface 8d or. 7d of the base area 8a or. 7a of the other piston part 8th , 7 is present. This leads to how best to get out of the 2nd and 3rd shows that the two piston parts 7 and 8th due to the pressure spring 6 due to the wedge gear against the inner wall of the housing 2nd be pressed, causing a large area of the two piston parts 7 and 8th on the inside wall of the case 2nd and thus a large power transmission area is guaranteed.

The third piston part 9 is with its free end 10th opposite other end 12th against the axial axis A pivotable with the second piston part 8th connected. For this purpose, the second piston part 8th a front indentation 13 and the third piston part 9 a corresponding front bulge 14 on. In the illustrated embodiment, the front indentation 13 wedge-shaped and the front bulge 14 wedge-shaped.

The spring contact pin 1 can, especially if several spring contact pins at the same time 1 used in a carrier 15 be plugged in.

The spring contact pin 1 is used in particular to make contact with an electronic component of a test object 17th , where an electrical contact 16 the electronic component within a socket-shaped receptacle 18th not in the axial direction of the spring contact pin 1 is arranged, but laterally offset, for example at the edge of the recess 18th .

Inside the recess 18th of the examinee 17th is in the area above the electrical contact 16 For example, a leaf spring, not shown, arranged when inserting the free contact end 10th the spring contact pin 1 ensures that the free contact end 10th on the electrical contact 16 is pressed, ie the leaf spring acts transversely to the direction of insertion.

If now the contact pin 1 with the free contact end 10th into the recess 18th of the examinee 17th is inserted, based on the undeflected position 2nd the third piston part 9 and thus the free contact end 10th opposite to the axial direction A towards electrical contact 16 of the examinee 17th deflected or pivoted. The fulcrum lies in the spherical area 11 of the third piston part 9 . Starting from the undeflected position ( 4th ) the bulge on the front side moves 14 of the third piston part 9 in the sense of the figures slightly upwards and thereby acts on the keyway-shaped front indentation 13 on the second piston part 8th , so that on the one hand the second piston part 8th by a certain amount a with respect to the axial axis A radially upwards and on the other hand in the axial direction A is shifted by a dimension x in the direction of the compression spring. This reduces the axial distance L ( 4th ) on Lx ( 5 ).

Because of this design, on the one hand, there is a sufficiently large electrical contact area between the third piston part 9 and the second piston part 8th ensured and on the other hand, the contact between the first piston part 7 and the second piston part 8th with the inside wall of the case 2nd further improved. This is the spring contact pin 1 suitable for high current applications where the touch contact direction is from the axial direction A deviates.

Of course, the invention is not limited to the illustrated embodiment. Further configurations are possible without leaving the basic idea. So the front indentation 13 also concave and the front bulge 14 also be convex, causing deflections of the piston part 9 against the axial axis A enabled in two spatial directions.

Reference list

1

Spring contact pin

2nd

casing

3rd

External thread

4th

Sleeve

5

End stop

6

Compression spring

7

First piston part

7a

Base area

7b

Axial range

7c

Wedge surface

7d

Wedge surface

8th

Second piston part

8a

Base area

8b

Axial range

8c

Wedge surface

8d

Wedge surface

9

Third piston part

10th

Free piston end

11

Spherical area

12th

Another end

13

Frontal indentation

14

Front bulge

15

carrier

16

Electric contact

17th

Examinee

18th

Bush-shaped receptacle

A

Axial direction

Claims (6)

Spring contact pin with an electrically conductive tubular housing (2) in which an electrically conductive piston acted upon by a compression spring (6) is guided, the free piston end (10) protruding from the housing (2) in electrical contact with an electronic component of a test object (17) can be brought, the housing (2) having a circumferential end stop (5) on the inside for the piston and the piston having a first piston part (7) resting on the compression spring (6) and a second piston part (8), wherein each piston part (7, 8) has a cross-sectionally round base region (7a, 8a) and a cross-sectionally semicircular axial region (7b, 8b), the two axial regions (7b, 8b) being arranged next to one another transversely to the axial direction (A) and at the free end each have a wedge surface (7c, 8c) which bears on a corresponding wedge surface (8d, 7d) of the base region (8a, 7a) of the other piston part 88,7), such that s the two piston parts (7, 8) are pressed against the inner wall of the housing (2) by the pressure spring, characterized in that the piston has a third piston part (9) which bears against the end stop (5) of the housing (2), protrudes from the housing (2) with its free contact end (10) and is pivotally connected with its other end (12) to the second piston part (8) with respect to the axial axis (A). Spring contact pin after Claim 1 , characterized in that the third piston part (9) has a spherical region (11) lying against the end stop (5) of the housing (2). Spring contact pin after Claim 1 or 2nd , characterized in that the second piston part (8) has an end recess (13) and the third piston part (9) has a corresponding end recess (14). Spring contact pin after Claim 3 , characterized in that the front indentation (13) is wedge-shaped and the front indentation (14) is wedge-shaped. Spring contact pin after Claim 3 , characterized in that the front indentation (13) is concave and the front indentation (14) is convex. Spring contact pin after Claim 5 , characterized in that the indentation (13) and the bulge (14) are conical, spherical or spherical.

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